Answer:
Explanation:
Mass of steel ball is 2kg
m=2kg
The steel ball is release from rest at a height h
H=1m
To a hit a steel plate of mass 8kg
M=8kg
Spring constant k=100N/m
Coefficient of restitution e =0.9
Coefficient of restitution is also give as
e =√(P.E after collision / P.E before collision)
Then, the P.E before collision is given as
P.E(before) = mgH=2×9.81×1 =19.62J
P.E(before) =19.62J
The P.E after collision can be model as the potential of the spring and it is given as
P.E(after) = ½kx²
P.E(after) = ½ ×100x²
P.E(after) = 50x²
Then, e = √P.E(after)/P.E(before)
0.9=√(50x²/19.62)
Square both sides
0.9² = 50x²/19.62
0.81 = 2.5484x²
x² = 0.81/2.5484
x² = 0.3178
x=√0.3178
x = 0.564m
The plate travelled 0.564m after impact
2. Coefficient of restitution is also give as
e =√(P.E after collision / P.E before collision)
P.E(after) =mgh
P.E(after) =2×9.81×h
P.E(after) =19.62h
where h is the rebound height
Now, the potential energy before collision is the sum of the spring potential energy and the potential energy of ball
P.E(before) = mgH +½kx²
P.E(before) = 2×9.81×1 + ½×100×0.564²
P.E(before) = 19.62 + 15.89
P.E(before) =35.51J
Now applying the formula
e = √P.E(after)/P.E(before)
0.9 =√19.62h/35.51
Square both sides
0.9² = 0.55h
0.81 =0.55h
h=0.81/0.55
h=1.47m
This is due to the fact that the spring will send the ball higher
